SERVICING MANUAL FOR ZX SPECTRUM® • LIST OF CONTENTS INTRODUCTION SECTION 1 SYSTEM DESCRIPTION SECTION 2 DISASSEMBLY/ASSEMBLY SECTION 3 SETTING UP AND SYSTEM TEST SECTION 4 FAULT DIAGNOSIS AND REPAIR SECTION 5 PARTS LISTS i LIST OF ILLUSTRATIONS i Fig No. ZX Spectrum Block Diagram Expansion RAM RAS/CAS Timing (Read Cycle shown) Keyboard Matrix Interconnections ZX Spectrum (Issue 2) Circuit Diagram ZX Spectrum (Issue 3) Circuit Diagram 1.1 1.2 1.3 1.4 1.5 Keyboard Format Speaker Load Input Waveforms Expansion Memory 1C Locations Issue 3 Links vs 1C Manufacturer and Type 4.1 4.2 4.3 4.4 Printed Circuit Board Printed Circuit Board Printed Circuit Board 5.1 5.2 5.3 (Issue 2) Component Layout (Issue 3) Component Layout (Issue 3B) Component Layout Prepared by THORN (EMI) DATATECH LTD for SINCLAIR RESEARCH LTD © Sinclair Research Ltd. (i) MARCH 1984 - INTRODUCTION This manual is for use by authorised SINCLAIR dealers, engineers and representatives as a guide to rectifying f a u l t s on the SINCLAIR ZX SPECTRUM personal computer. The m a n u a l refers p r i n c i p a l l y to the Issue 2 and Issue 3 Spectrums but provides a background to the Issue 1 version in the section dealing with m o d i f i c a t i o n history. Basic knowledge of ZX SPECTRUM operating procedures is assumed as is knowledge of current workshop practice relating to microcomputers. NOTE: Essential modifications are required on some Issue 2 Spectrums. Refer to M o d i f i c a t i o n History (Section 4) and implement as necessary. - SAFETY MEASURES• This instruction — WARNING — manual and contains CAUTION certain - notices which MUST be- followed by the user to ensure SAFE operation and to retain the equipment in a SAFE condition. Any adjustment, maintenance and repair of the opened apparatus under voltage shall be carried cut only by a skilled person who is AWARE OF THE HAZARD INVOLVED. SECTION 1 SYSTEM Sub-Section 1 2 3 4 6 1.1 2. LIST OF CONTENTS Introduction Architecture Z80A CPU Memory Organisation Read/Write Operations Input/Output TV Picture Generation Keyboard Scanning Tape Interface Power S u p p l i e s Circuit Diagrams ZX Spectrum, Issue 2 ZX Spectrum, Issue 3 5 1. DESCRIPTION Page No. 1.1 1.1 1.2 1.4 1.4 1.6 1.6 1.8 1.10 1.11 Fig. 1.4 Fig. 1.5 INTRODUCTION A block diagram of the complete ZX SPECTRUM micro-computer is given in Figure 1.1. It is valid for all build standards, fitted with either 16k or 48k bytes of dynamic RAM memory. Although functionally identical, detailed circuit changes have been introduced to improve reliability and to assist with manufacture. The printed circuit board layout has also been modified. Details of these changes are highlighted where necessary in the following paragraphs, and in later sections referring to fault diagnosis and repair. ARCHITECTURE 2.1 The architecture of the Spectrum shown in Figure 1.1 is typical of many microcomputer systems in that it comprises a single microprocessor board (in this instance a Z80A or u 780 C P U ) , a read only memory (ROM), an expandable RAM memory and an input/output section h a n d l i n g the keyboard, tape and TV display functions. The latter is recognisable as the logic gate array (ULA) and the three functional blocks shown in the right of the diagram. 2.2 The computer is built on a s i n g l e printed circuit board which also includes a regulated power supply fed from an external 9V power pack. The keyboard matrix is part of the upper case assembly and is connected to the board via two ribbon cables KB1 and KB2. A description of each section follows. 1.1 3. Z80A CPU 3.1 The Z80A is an 8-bit s i n g l e - I C central processing unit (CPU). It is clocked at 14.0 MHz from an external source controlled by the logic gate array (ULA) and has a standard three bus input/output arrangement. These buses are the Data Bus, Address Bus and Control Bus respectively. 3.2 Data Bus. D7-D10 constitutes an 8-bit b i - d i r e c t i o n a l data bus with active h i g h , t r i - s t a t e input/outputs. It is used for data exchanges with the memory and with the ULA. 3.3 Address Bus. A15-AO constitutes a 16-bit address bus with active h i g h , tri-state outputs. The address bus provides the address for memory (up to 64k bytes) data exchanges and for data exchanges with the ULA. It is also used d u r i n g the interrupt routine (see below) when scanning the keyboard matrix. 3.4 Control Bus. The control bus is a collection of i n d i v i d u a l s i g n a l s which g e n e r a l l y organise the flow of data on the address and data buses. The b l o c k diagram only shows five of these s i g n a l s a l t h o u g h others of minor importance are made a v a i l a b l e at the expansion port (see Figures 1.4 and 1.5 for d e t a i l s ) . 3.5 Starting with memory reguest f M R E Q ) , this signal is active low i n d i c a t i n g when the address bus holds a v a l i d address for a memory read or memory write operation. Input/Output reguest ( I O R Q ) is also active low but indicates when the lower half of the address bus holds a v a l i d I/O address for the ULA d u r i n g I/O read/write operations. 3.6 The read and write s i g n a l s ( R D and W R ) are active low, and one or other is active i n d i c a t i n g that the CPU wants to read or write data to a memory l o c a t i o n or I/O device. All the control s i g n a l s discussed so far are active low, tri-state outputs. The control signal described here is the interrupt last maskable (INT). This input is active low and is generated by the ULA once every 20 ms. Each time it is received the CPU ' c a l l s ' the ' m a s k a b l e i n t e r r u p t ' routine d u r i n g which the real-time is incremented and the keyboard is scanned. 3.7 3.8 CPU Clock. R e t u r n i n g to the CPU clock mentioned earlier in t h i s section, the ULA is able to inhibit this input bringing the CPU to a temporary halt. This mechanism gives the ULA absolute priority, a l l o w i n g it to access the standard 16k RAM without interference from the CPU (see RAM description). Switching transistor TR3 ensures that the clock a m p l i t u d e is +5V rather than some arbitrary TTL l e v e l . This is essential if the CPU is to operate e f f e c t i v e l y while executing fast machine code programs of the 'space i n v a d e r ' ^' 1.2 3.9 Dynamic Memory Refresh. The CPU incorporates b u i l t - i n dynamic RAM refresh circuitry. As part of the instruction OP code fetch cycle, the CPU performs a memory request after first p l a c i n g the refresh address on the lower eight bits of the address bus. At the end of the cycle the address is incremented so that over 255 fetch cycles, each row of the dynamic RAM is refreshed. This mechanism only applies to the optional 32k expansion RAM in the 48k Spectrum. An alternative refresh method is adapted for the standard 16K RAM. 4. MEMORY ORGANISATION 4.1 In the standard 16k Spectrum there are 32k bytes of addressable memory e q u a l l y divided between ROM and RAM. 4.2 The lower 16k bytes of memory (addresses 0000 - 3FFF) are implemented in a single ROM (IC5) which holds the monitor program. This program is a complex Z80 machine code program divided broadly into three parts one each covering the input/output routines, the BASIC interpreter and expression h a n d l i n g . Details of the program content, although outside the scope of this m a n u a l , are referred to as necessary. 4.3 The upper 16 bytes of memory (addresses 4000 - 7FFF) are implemented using eight 16k bit dynamic RAMs (IC6-IC13). Approximately h a l f of this space is a v a i l a b l e to the user for w r i t i n g BASIC or machine code programs. The remainder is used to hold the system v a r i a b l e s i n c l u d i n g 6k bytes reserved for the memory mapped d i s p l a y area. 4.4 In the 48k Spectrum an a d d i t i o n a l 32k bytes of RAM are provided (addresses 8000 - FFFF) which are implemented using eight 32k bit dynamic RAMs (IC15-IC32). The RAM, providing extra memory space for the user, is normally fitted d u r i n g m a n u f a c t u r e but may be added retrospectively using the RAM expander kit. In addition to the RAMs, the kit includes the address m u l t i p l e x e r and read/write control ICs IC23-IC26. Board space and the necessary discrete components are already provided on the board. 4.5 Read/Write Operations 4.5.1 The following description should be read in conjunction with the circuit diagrams given in Figures 1.4 and 1.5. 4.5.2 Read Only Memory (ICS). The CPU addresses the ROM directly during memory read cycles using the address bus A13-AO. MREQ and RD enable the ROM and the ROM outputs respectively. A third input (CS) derived by the ULA 'ROMCS) selects the ROM, provided the higher order address bits A14 and A15 are both low. These are reserved for accessing the RAM memory which starts with address 4000 (i.e. address A14 set). An external ROM 1C select input, supplied via the expansion port on pin 25A, selectively disables the on-board ROM by pulling the select input high. By virtue of R33 placed on the ULA side of the ROM the ULA ROMCS output is effectively inhibited. Interface 1 uses this 1.4 m e c h a n i s m a l l o w i n g the CPU to read the extension ROM in the interface for m i c r o d r i v e and RS232 a p p l i c a t i o n s . 4.5.3 L i n k s H and N, shown directly above IC5, a l l o w a second source ROM to be fitted. The Hitachi (H) and NEC (N) ROMs use different pins for the enable and select inputs (i.e. pins 20 and 2 7 ) . The l i n k s a l l o w the inputs to be reversed accordingly. 4.5.4 Standard 16k RAM (IC6-IC13). The eight 16k RAM ICs m a k i n g up the standard 16k x 8 bit RAM memory are organised as a matrix of 128 rows x 128 columns. Thus, separate 7-bit row and column addresses are reguired to access any one of the locations. These addresses are s u p p l i e d by the CPU on address bus A13-AO via an address multiplexer IC3/IC4. The low order address bits A6-AO give the row address and are selected at the b e g i n n i n g of the memory access cycle when i n i t i a l l y the RAS output from the ULA is high. Later, as the row address is latched, RAS goes low selecting the high order address bits A13-A7 giving the c o l u m n address. 4.5.5 The RAS/CAS outputs from the ULA are generated in seguence in response to MREQ and A14 from_the CPU. The DRAMWE output, a l s o from the ULA is a decode of the RD/WR waveforms t e l l i n g the RAM to expect either a read or a write cycle. 4.5.6 It is also apparent from the circuit diagram that the ULA can access RAM by generating a set of addresses independent of those generated by the CPU. The address port for the RAM is therefore d u a l l e d by the i n s e r t i o n of small value resistors (R17-R23) on the address m u l t i p l e x e r side of the RAM. This ensures that where there is likely to be conflict between the ULA and CPU, the ULA address has priority. Priority is assigned on the basis that the ULA must access the memory mapped d i s p l a y area in the RAM at set i n t e r v a l s in order to b u i l d up the video for the TV d i s p l a y . If the ULA is about to access the RAM and it detects either A14 or A15 (i.e. the CPU is also about to access the RAM) the ULA i n h i b i t s the CPU clock temporarily h a l t i n g the CPU memory transaction until its own transaction is completed. 4.5.7 Resistors Rl to R8, in series with the data bus lines, perform a s i m i l a r function to the address portplr£sistors described above. They ensure that the ULA does not 'see' CPU write data w h i l e the ULA is accessing the RAM. 4.5.8 Refresh for the standard 16k dynamic RAM is accomplished during normal read cycles, i.e. most rows are refreshed each time the ULA accesses the memory mapped display area d u r i n g picture compilation; the remaining rows are refreshed as a result of other read cycles also known to occur at regular intervals w i t h i n the refresh period. 1.5 4.5.9 32k Expansion RAM (IC15-IC32). The eight 32k ICs m a k i n g up the 32k x 8 bit expansion RAM are in fact 64k ICs with either row or column drop-out rendering one half of the memory n o n - f u n c t i o n a l . In order to accommodate the Texas Instruments RAM (Type TMS 4532) or the optional OKI RAM (Type MSM3732) a set of l i n k s are provided, v i s i b l e on the c i r c u i t diagram above the address m u l t i p l e x e r IC25/IC26. These l i n k s not only cater for the different m a n u f a c t u r e r (Issue 3 Spectrums o n l y ) but a l s o a l l o w , in both instances, one of two 1C versions to be selected depending on which h a l f of the RAM (top, bottom, left or right) is f u n c t i o n a l . The l i n k s are respectively TI and OKI (manufacturer - Issue 3 Spectrums o n l y ) , -3/-4 (TI version) and -H/-L (OKI version - Issue 3 Spectrums o n l y ) . NOTE: It is essential when replacing ICs in this area that all RAMs carry the same manufacturers part number and that the l i n k s are selected a c c o r d i n g l y . 4.5.10 The expansion RAM is organised as a matrix of 128 rows x 256 columns (TI RAMs) or 256 rows x 128 (OKI RAMs). Thus, separate 7/8 bit row and column addresses are required to access any one of these l o c a t i o n s . These addresses are supplied by the CPU on address bus A14-AO via an address m u l t i p l e x e r IC25/IC26. For example, when accessing the TI RAM the low order address bits A6 to AO give the row address; AR is h e l d low on the -3 version selecting the top half of the memory and high on the -4 version selecting the bottom h a l f . The column address is given by the high order address bits A14-A7. 4.5.11 Row/column address selection and RAS/CAS t i m i n g for the RAM is decoded in IC23/IC24 from inputs s u p p l i e d by the CPU, i.e. address l i n e A15 selecting addresses 8000 upwards, and MREQ heralding a memory read or write cycle. A theoretical t i m i n g diagram i l l u s t r a t i n g the RAS/CAS waveforms is given in Figure 1.2. 5. INPUT/OUTPUT 5.1 The input/output section of the Spectrum is centered round the ULA (IC1). The functions performed w i t h i n the device i n c l u d e TV video c o m p i l a t i o n , keyboard scanning and tape input/output. It also derives and controls the CPU clock (<j>CPU) using an external 14 MHz crystal XI, and drives the loudspeaker when a ' B E E P ' instruction is being executed. Each of these sections and the supporting circuits are described below. 5.2 TV Picture Generation 5.2.1 The video c o m p i l a t i o n section of the ULA operates in conjunction with the memory mapped picture display area in the standard 16k RAM, the colour (chrominance) modulator (IC14) and the UHF modulator. This combination produces a high resolution, 24 l i n e x 32 character, eight colour TV d i s p l a y . 1.6 FIG 1.2 EXPANSION RAM RAS/CAS TIMING 1.7 (READ CYCLE SHOWN) 5.2.2 U s i n g the 14 MHz clock the ULA derives l i n e and f i e l d t i m i n g compatible with the external TV receiver. Video is derived by accessing the memory mapped display area in the RAM in a set seguence at set times throughout the picture frame. The addresses are necessarily independent of the CPU and appear on the ULA address lines A6 through AO as two separate bytes timed by the RAS/CAS row/column address select l i n e s . 5.2.3 The net result is three separate video waveforms outputs from the ULA on pins 15, 16 and 17. These carry the l u m i n a n c e signal Y, i n c o r p o r a t i n g the l i n e and field sync, and two u n m o d u l a t e d c o l o u r difference s i g n a l s U and Y m a k i n g the Spectrum c o m p a t i b l e with both colour and monochrome receivers. 5.2.4 From the ULA the colour difference s i g n a l s are a p p l i e d to the colour m o d u l a t o r IC14 via two level s h i f t i n g networks. These match the ULA output levels with those reguired at the B-Y and R-Y inputs to the modulator. In the Issue 2 Spectrum the l e v e l s h i f t i n g network is passive, incorporating two potentiometers VR1, VR2. These are reguired to set-up the chroma b i a s level on IC14 pin 3 such that the voltage difference measured between pin 3 and the colour difference s i g n a l s on pins 2 and 3 respectively is n o m i n a l l y 0V d.c. In the Issue 3 Spectrum two active networks i n c o r p o r a t i n g IRS and TR9 e l i m i n a t e the potentiometers, greatly i m p r o v i n g colour stability. 5.2.5 The level shifted c o l o u r difference s i g n a l s , input to IC14, are then encoded, by guadrature m o d u l a t i n g two 4.43 MHz chroma sub-carriers. The sub-carriers are generated with the assistance of an external crystal X2 and a CR l e a d / l a g network introducing a 90° phase shift between pins 1 and 18. (A further difference between the Issue 2 and 3 Spectrums lies in the bias o s c i l l a t o r . The early issues incorporate a trimmer TC2 a l l o w i n g the chroma sub-carrier freguency to be adjusted; on the later issues the freguency is f i x e d ) . The resultant m o d u l a t e d colour difference s i g n a l s are f i n a l l y mixed producing a composite chroma sub-carrier at IC14 pin 13. 5.2.6 At this point the chroma s i g n a l is a.c. coupled to the base of TR2 and added to the inverted luminence signal on TR1 collector. The resultant composite video is then buffered and a p p l i e d to an encapsulated U H F m o d u l a t o r operating on European standard channel 36. 5.3 5.3.1 Keyboard Scanning Every 20 ms (i.e. once per m a s k a b l e i n t e r r u p t ) , the CPU systematically scans the keyboard recording which 'keys '(if any) have been pressed. The s c a n n i n g method is described below with the aid of Figure 1.3. As the figure c l e a r l y i l l u s t r a t e s the keyboard consists of an 8 x 5 m a t r i x , the inter-section of each row and column bridged by a n o r m a l l y open switch contact. The row ' o u t p u t s ' and column ' i n p u t s ' are shown connected by separate ribbon cables KB1 and KB2, one to the ULA and the other to the high order address lines A15-A8. P u l l - u p resistors R64 through R68 ensure that when the address bus is in the high Z state, or none of the key-switches is closed, row outputs KBO to KB4 remain h i g h . 5.3.2 When the keyboard s c a n n i n g routines are entered the CPU performs successive I/O read cycles setting the IOREQ and RD lines to the IJLA, low. At the same time, the I/O port addresses placed on the upper h a l f of the address bus are m o d i f i e d with each cycle such that each of the address l i n e s A15 through A8 is set l o w in t u r n , the other l i n e s remaininghigh. 5.3.3 The seguence starts with I/O port address FE d r i v i n g address line A8 low. The keyboard matrix also sees t h i s potential on column 6 a p p l i e d via D6 and the ribbon cable KB2. Thus, when any of the switches on the inter-section with column 6 is pressed, the corresponding row output s u p p l y i n g the ULA via the second ribbon cable (KB1), is p u l l e d low. The row s i g n a l ( s ) is subseguently inverted by the ULA and placed on one of the five low order data bus l i n e s . For e x a m p l e , if the CAPS SHIFT key is pressed row one output drives data bus DO high and so on. The seguence ends with I/O address 7F when c o l u m n 8 is addressed. In t h i s instance, operation of the SPACE key drives DO h i g h . C l e a r l y , the keyboard scanning routines make the d i s t i n c t i o n between the CAPS SHIFT and SPACE key by knowing which address l i n e is being driven. 5.4 Tape Interface 5.4.1 When LOADing or SAVEing programs using a cassette recorder, the ULA transfers i n f o r m a t i o n between the M I C and EAR sockets and the data bus, performing A/D and D/A conversions as reguired. Since the LOAD and SAVE functions are m u t u a l l y e x c l u s i v e , a s i n g l e pin on the ULA (i.e. pin 28) is used both for input and output. Separate I/O read/write cycles to port address 254 configure the pin accordingly. During the LOAD operation the CPU executes successive I/O read cycles, reading the EAR input off data bus 6. When performing a SAVE operation, the CPU executes successive I/O write cycles, this time w r i t i n g data to the MIC output via data bus 3. 5.4.2 To ensure that I/O cycles are correctly implemented, the IOREQ l i n e s u p p l y i n g the ULA is gated with address l i n e AO via TR6. Thus, if any memory transactions occur where AO is high (i.e. not port address 254) then the IOREQ input is forced high i n h i b i t i n g any attempt to perform an I/O cycle. 5.4.3 Loudspeaker (BEEP) Operation. It should be noted that w h i l e SAVEing, the level of the MIC output is barely sufficient to drive the loudspeaker via D9 and TR7 (D10). However, during the execution of a BEEP instruction the CPU writes instead to port 254 on data bus 4. This e f f e c t i v e l y boosts the MIC output, d r i v i n g the loudspeaker so that the BEEP tone can be easily heard. During the execution of such an instruction the cassette recorder is not r u n n i n g so there is no c o n f l i c t at the MIC/EAR sockets. 1.10 6. 6.1 POWER SUPPLIES The on-board power s u p p l y unit receives a 9V u n r e g u l a t e d supply from the external S i n c l a i r ZX power pack and derives the f o l l o w i n g internal supply r a i l s : (a) regulated +5V for the 1C logic c i r c u i t s , the ULA and the U H F modulator, (b) -5V and +12V for the standard 16k dynamic RAM, (c) +12V for the colour m o d u l a t o r circuits. 6.2 The external power pack incorporates a m a i n s transformer, f u l l wave rectifier and c a p a c i t i v e smoothing. A thermal fuse is fitted at the transformer input. 6.3 The on-board power supply unit incorporates a 7805 r e g u l a t o r , d e r i v i n g the +5V power r a i l , and an inverter stage TR4/TR5. The latter raises the level of the +9V unregulated s u p p l y to in excess of +12V. The resultant sguare wave at the junction of TR4 collector and the inverter coil is subseguently rectified and smoothed by D5/C44 producing the +12V output for the RAM. A d d i t i o n a l smoothing, imparted by R62/C45, produces the +12V supply for the TV circuits free from noise generated by the RAM. The sguare wave at TR4 collector also supplies the Zener/rectifier diode combination D16/D12 generating -5V for the RAM, and is a v a i l a b l e at the expansion port for use by peripherals. The +12V, +5V and -5V are also made a v a i l a b l e . SECTION 2 DISASSEMBLY/ASSEMBLY Sub-Section 1. LIST OF CONTENTS Page No. 1 Disassembly 2.1 2 Assembly 2.1 DISASSEMBLY 1.1 U n p l u g all input/output leads and turn the computer upside-down to reveal five self-tapping screws. Remove the screws. Hold the two halves of the case together and return the computer to the keys uppermost position. The top half of the case can now be separated from the bottom h a l f , a l t h o u g h it remains connected to it by two f l e x i b l e keyboard ribbon connectors. Care should be taken not to damage the ribbon connectors. As an aid to reassembly, the lie of the connectors within the case should be noted. 1.2 To remove the board from the lower half of the case, remove one selftapping screw (adjacent to IC22 socket) and lift out the board. It may be advantageous to make up two short p l u g g a b l e extensions for the keyboard connectors in order to improve a c c e s s i b i l i t y to the board. 1.3 To change either the keyboard membrane or the rubber keyboard mat it is first necessary to remove the escutcheon plate (template). This is attached to the case by double-sided adhesive tape around the edges. The template is removed by inserting a screwdriver at one end and l e v e r i n g it away from the case. It is not n o r m a l l y possible to remove the template without damage. 2. ASSEMBLY 2.1 Assembly is carried out using the reverse procedure to disassembly. Do not overtighten s e l f - t a p p i n g f i x i n g screws. 2.2 When r e p l a c i n g a keyboard component, note that the membrane keys into projections on the case. Place the keypad over the membrane and ensure that it is positioned and seated properly. Faulty i n s t a l l a t i o n can result in depressed keys being trapped under the template during subsequent key operations. To install the template, place doublesided adhesive tape around all four edges, locate it in position on the case and apply firm pressure around the edges (12 mm tape on sides and bottom, 6 mm at top). 2.1 that of 2.3 When a l i g n i n g the top h a l f of the case with the bottom h a l f ensure that the two keyboard ribbon cables are not trapped between projecting components w i t h i n the case. In their correct positions there is s u f f i c i e n t room for the cables to take up a comfortably curved position i n s i d e the case. If a cable is trapped and bent d o u b l e , an open c i r c u i t w i l l sooner or later r e s u l t . SECTION 3 SETTING UP AND SYSTEM TEST Sub-Section 1. 1.1 LIST OF CONTENTS Page No. 1 General Alignment Introduction Voltage Check Colour Adjustment Sub-Carrier Oscillator 14MHz Oscillator 3.1 3.1 3.1 3.1 3.2 3.2 2 System Test 3.3 GENERAL ALIGNMENT Introduction. The Issue 3 Spectrum m o d i f i c a t i o n removes the need for adjustment of the colour t u n i n g u s i n g potentiometers and trimmers. Therefore, the setting-up procedure for this board is confined to checking that the i n t e r n a l l y generated power supply voltages and two oscillator frequencies are correct. Adjustment instructions apply strictly to the Issue 2 Spectrum boards only but are g e n e r a l l y relevant to the Issue 1 Spectrum as w e l l . To carry out the setting up procedure it is first necessary to remove the ZX SPECTRUM from the case (Section 2, A s s e m b l y / D i s a s s e m b l y ) . For convenience the keyboard may a l s o be disconnected. 1.2 Voltage Check. as f o l l o w s : Check that the i n t e r n a l l y generated power voltages are Circuit Reference IC6 pin 9 IC6 pin 1 IC6 pin 8 LT side of C52 1.3 Nominal Value + 5V - 5V +12V +12VA Tolerance ± ± ± 0.25V 5.5V to -4V 1.2V 1.2V Colour Adjustment. Potentiometers VR1 and VR2 are used to effectively n u l l the voltages between pins 4 and 2 (for VR1) and pins 2 and 3 (for VR2) on IC14 (LM1889). To a l l o w for thermal drift, the potentiometers are set for non-zero voltages; furthermore these voltage off-sets are set to satisfactory but non-optimum l e v e l s in production, and optimum values may be used to advantage in servicing. The relevant figures are given in the f o l l o w i n g t a b l e - voltages are given relative to pin 3 of LM1889. 3.1 Pot. 1.4 IC14 Factory Settinq Pin No. (mV) Optimum ( m V ) Voltage Tolerance Overall Ranqe (mV) VR1 4 130 ± 20 +50 -5 +45 to +150 VR2 2 75 ± 20 -50 -50 +5 -45 to -100 Sub-Carrier Oscillator. The chrominance frequency should be 4.433619 MHz ± 50 Hz. checked/adjusted by usinq one of two methods, below. sub-carrier o s c i l l a t o r This frequency may be listed in (a) or (b) A p p l y power to the power socket usinq a bench power s u p p l y set at 9V. Current consumption w i l l be approximately 500 mA to 700 mA for the 16k Spectrum and 700 mA to 900 mA for the 48k Spectrum. 1.5 (a) Feed the Spectrum m o d u l a t o r output via a co-axial cable into a standard colour TV receiver. Measure the frequency of the locked TV chroma sub-carrier. (b) Connect pin 17 of IC14 (LM1889) via a 4.7 pF capacitor and a lead to the frequency meter. It is recommended that this is done u s i n q a jiq made up from an 1C test c l i p . Pin 18 of this c l i p must be removed to m i n i m i s e stray capacitance. Connect a 10k ohm resistor between the input t e r m i n a l s of the frequency meter. Measure the frequency and adjust trimmer TC2 if the measured frequency is outside tolerance. 14 MHz Oscillator. This frequency is not readily set by workinq to a specified frequency and tolerance. On Issue 2 boards trimmer TCI s h o u l d be adjusted to m i n i m i s e the effects of beat frequencies which cause waves of distortion to flow across the screen. These are p a r t i c u l a r l y apparent with certain colour c o m b i n a t i o n s , e.g. red INK or green PAPER, and the phenomenon is sometimes referred to as 'dot crawl'. It is stressed that adjustment of this frequency is not s t r a i g h t - f o r w a r d , as d e v i a t i o n s due to temperature chanqe are easily v i s i b l e ; t u n i n q should be adjusted to m i n i m i s e rather than remove this effect. Proceed as follows: (a) Set up the Spectrum to display qreen PAPER with red INK. (b) Type-in three or four lines of characters and monitor the screen. (c) Adjust trimmer TCI to m i n i m i s e the effects of distortion. 3.2 2. SYSTEM TEST 2.1 The system test for the Spectrum may be undertaken using the ZXTP taped program (see 1.1 Test Equipment in Section 4) loaded conventionally; this requires that the keyboard is connected. The test should be carried out with the Spectrum connected to its own power supply. 2.2 The test program exercises all of the Spectrum circuitry with the exception of the SAVE function. To test this function a small, possibly one line program should be typed in, SAVED and then VERIFIED as described in the instruction manual. 3.3 SECTION 4 FAULT DIAGNOSIS AND REPAIR Sub-Section 1 LIST OF CONTENTS Introduction Test Equipment Modification History Modifications - Issue 1 Board Modifications - Issue 2 Board 32k Extension Memory - (16k-48k) Hitachi vs NEC ROM 2 Fault Diagnosis Techniques Power Supply Unit Initialisation Memory Check Keyboard Structure F a u l t - F i n d i n g Guide Page No. 4.2 4.2 4.3 4.4 4.5 4.5 4.6 4.6 4.6 4.7 4.7 4.8 4.10 4.11 3 Repair 4.19 4 16k to 48k Upgrade Integrated Circuits/Link Settings Issue 2 Board Issue 3 Board 4.19 4.19 4.20 4.20 1. INTRODUCTION 1.1 Test Equipment Section 4 is intended as a guide to fault diagnosis and repair of the ZX SPECTRUM. It is assumed that users have a reasonable knowledge of electronic servicing, theory and standard fault-finding techniques and have access to the test equipment and tools required to carry out the task. The table below contains a list of the minimum recommended test equipment and materials. SPECIFICATION/MANUFACTURER EQUIPMENT Oscilloscope with O s c i l l o s c o p e probe ( x l O ) Rise Time: Variable power supply unit 0 to 30V d.c. Mono cassette With RECORD and PLAYBACK facilities recorder 0.02 us/cm M a i n s extension lead 'Safebloc' type Multimeter General purpose Colour T e l e v i s i o n Open Market ZX Printer Sinclair ZXTP test tape Blank tape Open Market Double-sided adhesive tape 12mm and 6mm wide, Tesafix 959 (B.D.F. TESA) or 3M equivalent Engineers who are already f a m i l i a r with the S i n c l a i r ZX81 w i l l find some s i m i l a r i t i e s in the ZX SPECTRUM. The Spectrum, however, is a more sophisticated device with colour and sound circuitry. The ZX SPECTRUM is s u p p l i e d with either 16k or 48k of on-board RAM. The 16k version is wired so that it can be expanded to 48k by the addition of a number of appropriate p l u g - i n ICs. For details of the memory upgrade, see sub-section 4 of this section. See Section 5, Figures 5.1 and 5.2 for the layouts of the Issue 2 and Issue 3 boards respectively. 4.2 1.2 Modification History Two major m o d i f i c a t i o n s have been implemented on the Spectrum boards: (a) A m o d i f i e d layout of board (i.e. Issue 1, Issue 2 and Issue 3) Issue 1. This layout allowed for the 16k RAM to be mounted direct on the board, with the 32k extension consisting of a subsidiary board m o u n t i n g onto special O I L connectors. Approximately 26,000 units were manufactured. Issue 2. This layout allows for all 48k of RAM to be mounted direct on the board; sockets, ready for a memory update, are fitted on 16k versions. A small number of Issue 2 units were manufactured using disc capacitors for 47 pF and 100 )jF v a l u e s , but subseguently a x i a l s were introduced. Issue 3. This layout incorporates advanced circuitry for the colour t u n i n g , removing the need for potentiometers and trimmers and the associated adjustment. It a l s o a l l o w s for OKI ICs to be used in the 32k extension memory. The heatsink is a l s o redesigned and is relocated at the back of the case. (b) The Ferranti ULA, type 5C102, plus spider addition replaced by ULA type 5C112. 5C102. This ULA has a timing fault which was cured by connecting a 74LSOO 1C mounted on a miniature board and spider. This ULA was fitted to approximately 40,000 units. 5C112. This improved ULA has no spider m o d i f i c a t i o n , but has either a diode or resistor or transistor connected to it. The details are: Diode/resistor mod : 4k7 resistor from +12V to pin 30 on IC2 and diode (IN 4148) from pin 30 of IC2 to pin 33 of IC1. Transistor mod : TR6 (ZTX313) connected as f o l l o w s : Base to IC2, pin 30. Emitter to IC1, pin 33. Collector to IC2, pin 11. 6C001 This ULA alters the timing of the colour burst s i g n a l , and improves the performance of the Spectrum with certain television sets (e.g. H i t a c h i , Grundig) . It also causes the screen picture to be shifted by one character width to the left. NOTE: The values of certain components vary depending on which board and which ULA is used as follows: 4.3 Board Issue No ULA Type 2 5C112 2 6C001 3 6C001 Ik 10 k 470 470 n Ik 10 k Ik Ik Component R47 R49 R56 R63 220 8 220 220 a k2 n n fi 1.3 Modifications - Issue 1 Board A number of m o d i f i c a t i o n s were introduced, and these should be checked for and, if necessary, introduced retrospectively: (a) 100 pF capacitor between RAS and ground - necessary only when u s i n g ULA 5C102. (b) 470 pF capacitor between IC2, pin 28 and ground - required only when IC2 and RAM ICs are all of NEC manufacture. (c) 1 k resistor between RAS and 23V and 1 k resistor between CAS and 12V, only when RAM ICs are of National manufacture. R57 (330n) must be removed, and the 470 pF capacitor is not required. (d) 47 k resistor between pin 13 of LMI889 and ground - required only if the difference between white and y e l l o w colours is inadequate. (e) If disc capacitors are used for C41 and C49 (47 nF) they must be replaced by axial components. (f) Capacitor C46 (1 uF e l e c t r o l y t i c ) should be replaced by a h i g h temperature component. (g) This modification is required for efficient operation of certain machine code software and should be implemented on all units. It has been implemented in manufacture for a l l ULAs 5C112-2 and later. D14 R24 R27 R73 (h) replaced by C67 (100 pF) changed from 3k3 to Ik changed from 680 n to 470 n ( I k ) added between Id/32 and +5V A significant cause of problems has been found to be failure of the internal power s u p p l y transistor TR4. The circuit may be improved by changing the value of R60 from 100 n to 270 fl and connecting a 4.7 uF electrolytic (perferably r a d i a l type) with positive end to TR5 emitter (positive end of C34) and negative end to TR5 base (to R58). 4.4 1.4 Modifications - Issue 2 Board A number of m o d i f i c a t i o n s have also been introduced for the Issue 2 board. These should be checked a n d , if necessary, introduced retrospectively. (a) These components upgrading: R48 R49 R50 R72 C65 changed changed changed changed changed should be changed if colour quality needs from 4k7 to 2k2 from 18 k to 8k2 from 8k2 to 4k7 from 47 k (or 18 k) to 10 k from 100 yF to 22 yF (b) E a r l y Issue 2 boards were manufactured u s i n g a considerable number of 47 yF and 100 uF disc capacitors. C41 (47 nF) and C43 (100 nF) should be replaced with axial components to prevent undue risk of short circuits. (c) To prevent l i f t i n g of the keyboard template, a thin strip (6 mm wide) of d o u b l e - s i d e d tape was introduced to the top edge of the template. (Previously, only the other 3 edges had tape). This m o d i f i c a t i o n should be introduced whenever template l i f t i n g is found to be a problem. (d) See Items 1.3(g) and (h) above. 1.5 Modifications - Issue 3B Board Although f u n c t i o n a l l y s i m i l a r to the Issue 3 board, the layout differs. The DC converter design has been improved, p r o v i d i n g greater power supply r e l i a b i l i t y . Component changes are as f o l l o w s (see Fig 1.5 for details): C77 C49 R60 TR4 1.6 ( I Q O n F ) added changed from 47nF to 560pF changed from 270fl to 68n can be either ZTX650 or TIPP31 32k Extension Memory - (16k to 48k) Board Issue 1: The extension memory is s u p p l i e d as a p l u g - i n module which is inserted into sockets near the edge connector. The ICs used are either TI 4532-3 or TI 4532-4, and all ICs in a unit must be of the same type (i.e. all must be -3 or all must be -4). Board Issue 2: The extra memory is obtained by p l u g g i n g in 4 logic ICs and 8 memory ICs (see Sub-Section 4). The ICs used are either TI 4532-3 or TI 4532-4, and a l l ICs must again be of the same type. It should be noted that the RAM select signal is 0V for the -3 1C and +5V for the -4. A l i n k on the board provides the required select l e v e l . 4.5 Board Issue 3: This allows OKI ICs to be used in p l a c e of TI 4532. A g a i n , all ICs must be of the same designation. Appropriate links (2) must be fitted in the grid located on the board between the edgeconnector and the ' m i c ' jack socket. A g a i n the extra memory is obtained by p l u g g i n g in 4 logic ICs and eight memory ICs. 1.7 Hitachi vs NEC ROM D u r i n g m a n u f a c t u r e , w i r i n g l i n k s are selected and inserted in the board according to whether a Hitachi or NEC ROM is used. These l i n k s are marked 'H' and ' N ' as appropriate and are located as f o l l o w s . Board Issue 1 - between the ROM and the heat sink Board Issue 2 - beneath the raised portion of the heatsink Board Issue 3 - adjacent to the loudspeaker Clearly, if the ROM is changed for one of a different make, then these links must be changed as w e l l . 2. FAULT DIAGNOSIS 2.1 Techniques In a closed loop system such as a computer, because of the interdependence of numerous component parts, f a u l t diagnosis is not necessarily s t r a i g h t - f o r w a r d . In addition, because of the high speed cyclic operation, interpretation of any waveforms on control, data and address lines as being valid depends to a large extent on practical experience of the system. There are however, certain checks with v a l i d waveforms and levels that can be carried out before s u b s t i t u t i n g any integrated circuits. Experience has shown that the best method of i n i t i a l l y checking waveforms and levels can be to compare with the same point in a known serviceable board. The f o l l o w i n g pages provide a basic fault-finding procedure and furnish a l i s t of possible faults a l o n g with suggested ways of curing them. W i t h a densely populated board such as the ZX SPECTRUM, a careful physical examination of the board can sometimes indicate an obvious fault. Burst-out discrete components or an overheated track show up immediately, as do the attentions of an enthusiastic amateur. Bearing in mind the latter, short ^circuits , caused ,by h a i r l i n e solder splatter can be or several ohms resistance and can cause some very m i s l e a d i n g fault symptoms. Provided first principles are adhered to and a common-sense approach is adopted, it w i l l be found after a short space of time that fixing a faulty Spectrum is very much a routine operation. 4.6 2.2 Power Supply Unit The unstabilised external power supply unit is a source of some problems. The design is such that, at minimum input voltage (215V a.c.) and 1.4A output, the voltage trough should not be less than 7.0V; at maximum input voltage (265V a.c.) and 60QmA output, the voltage peak should be less than 13V. 2.3 Initialisation At switch-on the computer should automatically produce a clear screen with the statement 'initialise' and (01982 Sinclair Research Ltd d i s p l a y e d in the lower left section of the screen. This indicates that most of the system is working. If the Spectrum does not i n i t i a l i s e , carry out the following basic checks. Basic Checks. It is d i f f i c u l t to be specific in a f a u l t - f i n d i n g guide because of the large variety of fault conditions which can occur, but the f o l l o w i n g procedure, starting with a table of checks set out in order of priority, w i l l however isolate the major f a u l t area. FUNCTION CIRCUIT REF. Voltage regulator input +ve side of C50 Voltage regulator output +ve side of C34 On-board power supply outputs: +5V d.c. IC6 pin 9 -5V d.c. IC6 pin 1 + 12V d.c. IV6 pin 8 + 12VA(to IC14 only) LT end of C52 WAVEFORM/VOLTAGE +9V d.c. ± 2.0V. At less than +7V the regulator may not operate correctly. +5V d.c. ± 0.25V discernable ripple. +5V d.c. ± 0.25V discernable ripple. -5V d.c. +12V d.c. +12V d.c. no - no Clock pulses IC1 pin 32 TR3 base and collector IC2 pin 6 Address and data lines (following through to relevant ICs) RT side of R17-R23 Waveform of amplitude 3.5V RT side of R1-R8 14MHz squarewave at +5V amplitude, If these tests prove satisfactory check IC1 pin 14, IC2 pin 11 and IC5 pin 28 for +5V. Also check for ground at IC1 pin 40, IC2 pin 29 and IC5 p i n 14. If all is s t i l l satisfactory at this point and IC1 is the p l u g - i n type, replace IC1. If replacement of IC1 does not cure the f a u l t , check the address and data l i n e s of IC1, IC2 and IC5 for active data. It is possible that one of the Z80A or RAM control lines has become faulty therefore, comparing with a known serviceable board if p o s s i b l e , check the waveforms at the f o l l o w i n g points at origin and destination: (a) IC2: Pin 16 Pin 20 Pin 19 Pin 21 Pin 22 - INT - IDREQ - MREQ - M - WR Pin Pin Pin Pin (b) IC22: Pin 4 Pin 15 - Pin 3 "RAT CA3~ 17 - NM1 24 - WAIT 25 : fflCTEQ /b KtbM - WITE If no fault has been found and the computer s t i l l has not i n i t i a l i s e d , the fault could lie in the RAM. If the computer is a 48k m a c h i n e the 32k of expansion RAM can be isolated. An easy way of doing this, assuming that the ICs are not fitted into sockets, is to remove the +5V from IC25. This is probably best done by very carefully c u t t i n g the track to IC25 pin 16. If this operation clears the fault condition, the expansion RAM w i l l have to be further isolated. In either instance the point has been reached where it is necessary to start replacing ICs. Where the f a u l t persists after i s o l a t i n g the 32k expansion RAM it would be necessary to start changing i n d i v i d u a l ICs in the order of IC13 to IC6 ( R A M ) , IC1 ( U L A ) , IC2 (Z80A). After each change of 1C the unit must be powered up to check for correct i n i t i a l i s a t i o n . A method of f a u l t - f i n d i n g that can be used on both the 16k and 48k versions is to make up a 'test 1C' device. This may be done by using an 1C test c l i p , to which is attached a serviceable 1C (of the relevant type e.g. 4116 or 4532), to bridge across each suspect 1C in turn. This method is not guaranteed to work but can often save a lot of time u n n e c e s s a r i l y c h a n g i n g suspect ICs. Memory Check Where a Spectrum has i n i t i a l i s e d correctly but a RAM memory f a u l t is suspected, it is possible to find the faulty address and relate it to a faulty 1C by carrying out the f o l l o w i n g procedure: Key in the instruction: PRINT PEEK 23732 + PEEK 23733 * 256 The v a l u e printed should be: 4.8 (a) (b) for a 48k unit - 65535 for a 16k u n i t - 32767 The v a l u e printed in each instance is the last v a l i d memory l o c a t i o n , and in a serviceable u n i t would be as set out above. Therefore, if a different v a l u e , n, is printed the faulty l o c a t i o n w i l l be n + 1. If the v a l u e returned is less than 32767 the f a u l t l i e s in the o r i g i n a l 16k of RAM. The f o l l o w i n g example i l l u s t r a t e s the method of r e l a t i n g a faulty l o c a t i o n to a f a u l t y 1C. Example. If a 48k Spectrum is g i v i n g a memory of 25.25k key in the following instruction: PRINT PEEK 23732 + PEEK 23733 * 256 Assume the answer displayed is 43200, 43201 (stops at last v a l i d l o c a t i o n ) . therefore the faulty location is Key-in: POKE 43201,85 : PRINT PEEK 43201 (= answer A) If answer A is 85, key-in: POKE 43201,170 : PRINT PEEK 43201 (= answer B) If answer B is anything other than 170 look up in the f o l l o w i n g t a b l e which 1C to change (e.g. if answer B is 234 change IC21). S i m i l a r l y , if answer A is other than 85 refer to the table to find the faulty 1C. Data 85 IC6-IC13 Data 170 IC15-IC22 Size of Error Error Bit Faulty RAM location if: < 32767 > 32767 84 171 1 0 IC6 IC15 87 168 2 1 IC7 IC16 81 174 4 2 IC8 IC17 93 162 8 3 IC9 IC18 69 186 16 4 IC10 IC19 117 21 138 234 32 64 5 6 IC11 IC12 IC20 IC21 213 42 128 7 IC13 IC22 If there is more than one f a u l t y RAM location the first f a u l t identified w i l l have to be repaired before it is possible to proceed. 4.9 2.5 Keyboard Structure The keyboard is connected horizontally in eight blocks of five keys and vertically m It configuration. five follows blocksthat of if eight any block keys. of Figure five keys 4.1 shows fail the the fault is with KB2 circuitry or the 8-way membrane, and that if any block of eight keys fail the fault is with KB1 circuitry or the 5-way membrane. Possible keyboard faults are listed in paragraph 2.6 FIGURE 4.1 KEYBOARD FORMAT 4.10 2.6 Fault-Finding Guide As with any complex d i g i t a l equipment the possible fault permutations are vast, thus the following table is not intended to be an exhaustive list of the f a u l t s that might occur on the Spectrum. It is intended as a guide only to possible courses of action to f o l l o w when f a u l t s show up in p a r t i c u l a r areas of the c i r c u i t . These areas are listed in the table with sub-headings, in no p a r t i c u l a r order of priority. It is envisaged that the ZXTP test tape has been loaded, or an attempt has been made to load the tape, in order to check for a faulty c o n d i t i o n . AREA TV screen dead, smoke appears on switch-on. SYMPTOM TR4 base-collector shorted. ACTION Remove TR4 Short persists with TR4 removed. 1. Check TR5 and C44. 2. V i s u a l l y check track. 3. Check TR4. TR4 blows a g a i n . 1. Not i n i t i a l i s i n g . No '(C)1982 Sine!air. Research Ltd1 statement. No video. No video. Change TR4 and TR5 (even though TR5 checks out). 2. Check that TR5 circuit components are to latest specification. Follow fault-finding procedure, paragraph 2.2 ^above. ' y y y 1. 2. NOTE: Table 4.1 sets out typical s i g n a l s found on IC14 pins 1-18 IC14 pins 1-18. No video after ULA changed. Change IC1. Check TR1 and TR2. 1. V i s u a l l y check IC1 and socket, 3. Check for shorting between C65 and R53. 4. Carry out f a u l t - f i n d i n g procedure,para 2.2 above. 1. 2. 3. 4. Check voltage drop across R64. Check +5V regulator 0/P and +9V regulator I/P. Check PWR socket not shorted. Check power unit. AREA No video, SYMPTOM (contd) ACTION No VIDEO INPUT at IC14 pin 12. 1. 2. Check waveform at IC14 pin 13. If correct check TR1 and TR2. Check waveforms at IC1 pins 15, 16 and 17: If correct check VR1, VR2 (Issue 1 and Issue 2 boards). 3. 4. Corrupt Paper, after ULA change. - Change IC1. If +5V and VIDEO INPUT correct change modulator. 1. 2. Check IC1 socket. Check PWR socket is not intermittent. 3. Check IC1 pin 14 for +5V with no discernible ripple. No 3 MHz at IC2 pin 6. 1. 2. 3. 4. 5. 6. Low amplitude - check R25. Check TR3. Check IC1 pin 32 for 3 MHz. Check IC1 pin 39 for 14 MHz. Check crystal X I . Check IC1 pin 13 for +3V. AREA Video Incorrect. SYMPTOM ACTION Dark Screen. 1. 2. Dim ' S i n c l a i r ' Io9°- 1' Check +12V" 2. Check C65 for high impedance. 3. Check R52. 4. Check +5V on IC14 pin 3. Wavy lines across screen. 1. Self resetting. Press down on each electrolytic capacitor to see if lines disappear. If so change that capacitor. 2. Check crystal X2. 3. Check/change TR1 and/or TR2. 4. Check/change IC14. Check TR6. Random dynamic squares. Change C54. Paper area too low. Change IC1. Diagonal lines in the border area. Change R47. Distorted video. 1. 2. Colour tuning faults (Issue 1 and Issue 2 boards) Check t u n i n g . Change modulator. - VR1 or VR2 f a i l s to adjust IC14 pin 13 waveform. Check for +3V pin 13. Change C30. at IC1 V i s u a l l y check IC14 circuits. 1. Monitor IC14 trimming VR2. 2. Monitor IC14 trimming VR1. 3. Change IC14. pin pin 2 4 AREA Colour tuning faults, (cont'd) SYMPTOM VRl or VR2 d.c. shifts IC14 pin 13 waveform. ACTION Change IC14. Alternate dark lines Change IC14. on screen. No colour after trimming TC2: ICH pin 17 not oscillating 1. Check crystal X2. 2. Change ICH. 3. Change X2. ICH pin 17 oscillating but fails to tune. 1. Check for broken track, 2. Change TC2. 3. Change ICH. ICH pin 17 output correct but still no colour (boards at all Issue Nos). 1. With 'Sinclair' logo on screen ICH pin 2 and ICH pin 4 should be as follows: 2. Colour faults Pin screen. (Issue 1 - Issue 3 boards. Blue haze around 'Sinclair1 *-™°' Screen too yellow. If ICH pins 2 and 4 are correct, change modulator. Change crystal X2. If untunable Issue 1 and issue 2 boardsj chage ICH. Change ICH. AREA Colour faults (cont'd) Keyboard faults. SYMPTOM Intermittent colour. ACTION 1. Change TC2 (Issue 1 and Issue 2 boards). 2. Change IC14. Red, Blue or Green 'Sinclair' logo. Change IC1. Washed-out colours. Check TR2. KB1 fault. 1. Check for short on 2 or more of the 5 tracks. 2. Change membrane. KB2 fault. 1. 2. Regulator c o i l . Speaker. Dead keyboard. Change IC1. Wrong keyboard response. Change IC1. Keyboard response too fast. Change IC1. Coil excessively noise. Change c o i l . No speaker output. NOTE: Figure 4.2 shows typical waveforms in the speaker circuit Test program. Check for short on 2 or more of the 8 tracks. Change membrane. 1. 2. 3. 4. Check load input forms . Check TR7. Check D9. Change speaker. 'Tape Loading Error' output. Reload program. Paper area edges distort. Change IC1. wave- AREA Test Program. (cont'd) SYMPTOM Paper area corrupts d u r i n g tests. ACTION 1. Change IC1. 2. Carry out f a u l t - f i n d i n g procedure (paragraph 2 . 2 ) . Border colours are striped. Change IC14. Failure Carry out fault-finding procedure (paragraph 2.2). messages. 'Test Passed1 Chan5e IC1message not f l a s h i n g . Reduced memory size. 1. 2. Program Loading. Perform memory test, Change IC1. Keyboard does not a l l o w loading. See keyboard f a u l t s , Program f a i l s to load, 1. Check jack sockets f u l l y inserted. 2. If l o a d i n g stripes in border are unusually wide, check D13. 3. Check/change IC1. 'Program appears. Check/Change IC2. are FIGURE 4.2 SPEAKER LOAD INPUT WAVEFORMS 4.17 TABLE 4.1. IC14 (IML889) PIN SIGNALS Pin No. Signal 1 (CHROMA LEAD) SINEWAVE BOOmV, 0.2yS, d.c. 9.5V 2 (R - Y INPUT) 3 (CHROMA BIAS) d.c. 4 4.8V (B - Y INPUT) 5 0V (GROUND) 12 (VIDEO INPUT) 13 (CHROMA SUBCARRIER) 14 (R.F SUPPLY) 15 (SOUND TANK) 16 (CHROMA SUPPLY 17 (CHROMA OSCILLATOR OUTPUT) 18 (CHROMA LAG) 6,7,8 9,10, 11 NOTES: d.c. 12V unreg. 'LINKED1 12V d > c - SQUAREWAVE 0.2 us 4V P-P. D.C. 0.8V SINEWAVE BOOmV P-P 2 uS d.c. 9.5V Not Connected (1) Rails and signals taken on switch-on, computer displaying ' S i n c l a i r 1 y (2) No keys pressed (3) All d.c. levels positive wrt 0V 4.18 3. 3.1 4. 4.1 REPAIR Renewal of components should be carried out u s i n g recognised d e s o l d e r i n g / h e a t s i n k i n g techniques to prevent damage to the component or to the printed circuit board. Other points to be noted are: (a) When replacing a keyboard m a t r i x , take care that the ribbon connectors are f u l l y inserted into the board connectors, and are not k i n k e d during insertion. (b) Make sure there is a good contact made between the voltage regulator body and the associated heatsink in order to ensure adequate heat conduction. The heatsink h o l e in certain Issue 3 boards a l l o w s excessive play w h i c h could cause f o u l i n g of the edge connector. Take care in re-assembly that the h e a t s i n k is fitted away from the edge connector. (c) When the regulator is being replaced it is recommended that a suitable proprietary thermal grease is applied to the rear surface of the component body. (d) The m o d u l a t o r s h o u l d be replaced as a complete unit. (e) When r e p l a c i n g p l u g - i n ICs it is a d v i s a b l e to use the correct removal and insertion tools. Avoid c o n t a m i n a t i n g the connection p i n s by h a n d ! i n g . (f) When h a n d l i n g ICs take normal anti-static precautions. It is recommended that o n l y a s u i t a b l y earthed, low power s o l d e r i n g iron be used. (g) After any component has been renewed the circuit board s h o u l d be examined c a r e f u l l y , to ensure that there are no solder ' s p l a t t e r s ' which may cause short circuits between tracks or connector pins. 16k TO 48k UPGRADE Integrated C i r c u i t s / L i n k Settings For both the Issue 2 and the Issue 3 boards the memory upgrade is accomplished by p l u g g i n g four logic ICs and eight memory ICs into e x i s t i n g board sockets. Depending on the types of memory 1C used, appropriate circuit l i n k s must be fitted on the board. Figure 4.3 shows the layout of the area of the board containing the empty sockets. The Issue 3 board is shown which also gives positions (top left of diagram) of the l i n k s . 4.19 4.2 Issue 2 Board The ICs used on this board are as follows: 1C TYPE IC15 - IC22 IC23 74LS32 IC24 74LSOO IC25, IC26 NOTES: .3 TI 4532-3 or TI 4532-4 200ns (or 250ns) 74LS157 (NOT N a t i o n a l Semiconductors) (1) All external RAM ICs must be of the same type (i.e. all -3 or -4 v a r i a n t s ) . (2) LINK 3 on the board (IC26, pin 10) should be fitted if IC15-IC22 are type 4532-3. (3) L I N K 4 s h o u l d be fitted if IC15-IC22 are type 4532-4. Issue 3 Board The ICs used on this board are as follows: 1C TYPE IC15 - IC22 IC23 74LS32 IC24 74LSOO IC25, NOTES: (1) (2) TI 4532-3, TI 4532-4 or OKI MSM3732 200 ns (or 250ns) IC26 74LS157 (NOT National Semiconductors) All extension RAM ICs must be of the same type. Two l i n k s must be fitted on the board (grid located between edge connector and m/c jack socket) depending on memory manufacturer and type (high or low e n a b l e ) . See Figure 4.4 for l i n k positions vs manufacturer and 1C type. 4.20 FIGURE 4.4 ISSUE 3 LINKS vs 1C MANUFACTURER AND TYPE 4.22 SECTION 5 PARTS LIST Sub-Section LIST OF CONTENTS Page No. 1 Introduction 5.1 2 Notes to Table 5.2 5.1 1. INTRODUCTION 1.1 Parts lists for the ZX SPECTRUM are provided in table form; one for the case assembly (Table 5.1) and another for the board assembly (Table 5.2). The latter covers the Issue 2 and 3 Spectrums and is related to the board layout diagrams given in Figure 5.1 and 5.2. T a b l e 5.2 a l s o lists the a l t e r n a t i v e components which the service engineer w i l l o c c a s i o n a l l y f i n d on production versions of the Issue 2 board or may introduce retrospectively in order to improve performance. These components are listed in the column headed ' I S S U E 2 MODS' with references to notes against them. These notes are explained below- 2. NOTES TO TABLE 5.2 (1) The alternative values given for R47, R49, R56 and T63 are used if the ULA fitted is Type 6C001. (2) The alternative values for R48, R50, R72 and C65 are introduced to improve the colour q u a l i t y . (3) C74 is essential on all Issue 2 boards and s h o u l d be fitted retrospectively. At the same time R60 must be replaced with the larger v a l u e . (4) The introduction of alternative components for R24 and R27 is essential. At the same time C67 replaces D14 and R73 is added. (5) Issue 2 boards fitted with the Type 5C112 ULA have either a transistor (TR6) or diode/resistor m o d i f i c a t i o n (see Issue 2 circuit diagram for d e t a i l s ) . (6) On Issue 3 boards only crystal X2 must have a close tolerance s p e c i f i c a t i o n (i.e. 10 ppm absolute, 10 ppm 20°C to 60°C, 5 ppm per year.) (7) On Issue 3B boards, the d.c. converter design has improved r e l i a b i l i t y . R60 is changed from 270n to 68ft and C49 is changed from 47nF to 560pF. Capacitor C77 ( l O O n F ) has been added. 5.1 2.1 General Capacitor Change. Early Issue 2 units were manufactured u s i n g a considerable number of 47 nF and 100 nF disc capacitors. Where these occur the service engineer should take the opportunity to replace C41 and C49 with axial types. TABLE 5.1 CASE ASSEMBLY MANUFACTURER DESCRIPTION Assembled board as appropriate (Table 5.2) Moulded Upper Case Moulded Lower Case Keyboard Mat (Rubber) Keyboard Membrane N.F.I. Keyboard Template Rubber Feet Self Tap Screws (case f i x i n g s ) , 5 off D o u b l e - s i d e d adhesive tape 12 mm wide; Tesafix 959 B.D.F. Tesa D o u b l e sided adhesive tape 6 mm wide; Tesafix 959 B.D.F. Tesa Self Tap Screw (board f i x i n g ) , 1 off 5.2 TABLE Circuit Reference Issue 2 5.2 Issue 2 Mod BOARD ASSEMBLY Notes Issue 3 Rating/ To! Manufacture Type CAPACITORS ( U n l e s s otherwise stated a l l c a p a c i t o r s are a x i a l types) C1-C8 C25 C26 C27 C28 C29/C30 C31/C32 C33 C34 C35 C36 C37/C38 C39 C40/C42 C43 C44/C45 C46 C47 C48 C49 C50 C51 C52/C53 C54 C55-C62 C63 C64 C65 C66 C67 C68-C71 C72/C73 C74 C75 TC1/TC2 C76 C77 47 nF 22 yF 47 nF 1 yF 22 yF 47 nF lOOnF 47 nF 22 yF 10 nF 47 nF 33 pF 10 nF 47 nF lOOnF lOOyF 1 yF 22 yF 47 nF 47 nF 22 yF (7) 150pF 470pF 47 nF 47 pF lOOpF lOOyF 47 nF - 4.7WF - - - 22 yF (2) lOOpF - (4) (3) (7) 47 nF 25V, 10% 22 yF 10V,-10%+80% 47 nF 2 5 V , 10% 1 yF 50V,-10% 22 yF 10V,-10%+80% 47 nF 25V, 10% lOOnF 25V, 10% 47 nF 25V, 10% 22 yF 10V,-10%+80% 10 nF 25V, 10% 25V, 10% 33 pF 25V, 10% 10 nF 25V, 10% 47 nF 2 5 V , 10% lOOnF 25V, 10% lOOyF 16V,10%+80% 1 yF 50V,-10%+80% 22 yF 10V,-10%+80% 47 nF 25V, 10% 47/560pF 25V, 10% 22 yF 10V,-10%+80% Ceramic Elect. Ceramic Ceramic Elect. Ceramic Ceramic Ceramic Elect. Ceramic Ceramic Ceramic Ceramic Ceramic Ceramic Ceramic Elect. Elect. Ceramic Ceramic Elect. 150pF 47 nF 47 pF lOOpF 22 yF 47 nF lOOpF lOOnF 16 pF 4.7uF lOOnF Ceramic Ceramic Ceramic Ceramic Ceramic Elect. Ceramic Ceramic Ceramic Ceramic Elect. Ceramic 25V, 10% 25V, 10% 25V, 10% 2 5 V , 10% 25V, 10% 20V,10%+80% 25V, 10% 25V, 10% 25V, 10% 25V, 10% 5V min 25V, 10% 47 nF lOOnF 25V, 10% 25V, 10% Ceramic Ceramic COIL Circuit Reference Issue 2 Coil SPECTRUM Issue 2 Mod - Notes - 5.3 Issue 3 SPECTRUM Rating/ Tol - Manufacture Type 1703 CONNECTORS Reference EAR MIC PWR Description Manufacturer/ Part Number 3.5 mm jack socket 3.5 mm jack socket 2.1 mm co-axial socket KB1 5-way ribbon connector M o l e x 5229-05CPB KB2 8-way ribbon connector Molex 5229-08CPB CRYSTALS Circuit Reference XI X2 Issue 2 Issue 2 Mod 14.000000MHz 4.433619MHz Notes - Note (6) Issue 2 Mod Notes Issue 3 Manufacture Type 14.000000MHz 4. 433619MHz DIODES Circuit Reference D1-D9 D10 D11-D13 D14 D15 D16 Issue 2 1N4148 1N4148 1N4148 1N4148 BA157 5V1 - (4) - Issue 3 Manufacture Type 1N4148 1N4148 BA157 5V1 Signal Signal Signal Signal Rectifier Zener INTEGRATED CIRCUITS Circuit Reference Issue 2 Issue 2 Mod ICl(ULA) 5C102 5C112 IC2(CPU) Z80A/U780 IC3/IC4 74LS157N IC5(ROM) SPECTRUM SPECTRUM IC6-IC13 4116 IC14 LM1889 IC15-IC22 TI4532 IC23 IC24 IC25/IC26 74LS32N 74LSOON 74LS157N - Notes Issue 3 (1) 6C0001 Z80A/M780 74LS157N SPECTRUM 4116 LM1889 TI4532/ MSM3732 74LS32N 74LSOON 74LS157N Manufacture Type 48k 48k 48k 48k only only only only Ferranti Not N a t i o n a l NEC/Hitachi 150 ns Texas/ OKI Not National RESISTORS ( 1 / 4 W , 5% unless otherwise stated) Circuit Reference R1-R8 R9-R16 R17-R23 R24 R25 R26/R27 R28 R29 R30 R31 R32 R33 R34 R35 R36 R37 R38 R39 R40 R41 R42 R43 R44 R4B/R46 R47 R48 R49 RBO R61/R52 R53 R54 R55 R56 R57 R58 R59 R60 R61/R62 R63 R64 R65-R69 R70/R71 R72 R73 R74/R75 R76/R77 R78 VR1/VR2 Issue 2 470R 8K2 330R 3K3 180R 680R 10KO 1KB 1KO 220KO 100R 680R 15R 10KO 680R 1KO 3K3 3K3 1KO 1KB 1KO 3KO 5K1 1KO 22 OR 4K7 8K2 8K2 2K2 390R 100K 56R 220R 330R 1KO 1K8 100R 15R 220R 15R 10KO 220R 470Korl8K 2K2 Issue 2 Mod Notes 1KO (4) 1KO 2K2 10KO 4K7 (1) (2) (1) (2) 470R (1) 270R (3), ( 7 ) 470R (1) 10KO 1KO (2) (4) 5.5 Issue 3 470R 8K2 330R 1KO 180R 470 10K 10K 10K 220K 100R 680R 15R 10K 680R IK 1KO 3KO BK1 1KO 1KO 2K2 10KO 4K7 2K2 390 100K 56R 1KO 1KO 1K8 270R 15R 1KO 15R 10KO 220R 10KO 1KO 10KO 1KO 470R Rating Tol Issue 3B 1/2 or 1W 2% 2% 2% 2% 68R TRANSISTORS Circuit Reference Issue 2 Issue 2 Mod TR1/TR2 TR3 TR4 TR5 TR6 TR7 TR8/TR9 ZTX313 ZTX313 ZTX650/TIPP31 ZTX213 ZTX313 - Notes - (5) Issue 3 ZTX313 ZTX313 ZTX650 ZTX213 ZTX313 ZTX450 BC184 MISCELLANEOUS Reference REG Description Manufacturer/ Part Number 5V r e g u l a t o r 7805 MOD UHF M o d u l a t o r with E36 v i s i o n carrier (UK o n l y ) Loudspeaker 40 ohm T.V. Type M o d u l a t o r Screen Insulator Heatsink Astec UM1233 1740 Special (Issue 2 or 3) R e g u l a t o r F i x i n g s ( l ) Screw, ch hd. 4BA x 15/16 in (2) Washer, shk prf, 4BA (3) N u t , hex, 4BA OIL SKT 16-way (10-off) for 48k expansion RAM (16k model only) OIL SKT 14-way (2-off) for 48k expansion RAM (16k model only) OIL SKT 28-way for IC1 (ULA) GENERAL DATA Earliest version - very pale brown keys. Second version - grey keys Third/Fourth versions - grey keys, but heatsink now visible through the edge connector slot Early Spectrum plus - same as fourth type. Dissembly - after removing the screws, t i l t back, face up and carefully lift the top taking care not to break any of the keyboard tails. Heatsink - when operating computer with the heatsink removed to obtain access a temporary heatsink must be used made of anything as long as it fits under regulator. Circuit Diagram - idealised version on centre pages shows all modifications which should be made. Note that connecting items such as standard capacitors may not be shown. Edge Connector - 28 pin double-sided to which no interface may be inserted or removed whilst computer is switched on. Plugs & Cables - use only genuine Sinclair issue or HK plugs, etc. Power Supply Links - Where any possibility of fluctuating mains exists a transient suppressor should be fitted. - T1/T3 for Texas THS4532-3; T1/T4 for Texas TMS4532-4 1/H for OKI HSH3732H; 1/L for OKI MSM3732-L. Other Service/Repair Manuals by T.I.S. Include:- Rank A823 CTV Chassis Philips G8 CTV Chassis Thorn 3000/3500 CTV Chassis Thorn 8000/8004/8500/8600 CTV Chassis Rank T20/20A CTV Chassis The Tunbridge & McCourt T.V. Repair Manuals The Tunbridge Video Repair Manuals SERVICE DATA Modification of earplug: Connect a 330 ohm resistor between signal and earth leads of earplug to a l l o w earplug to be left in place while saving a programme. Inserting or removing such items as joysticks, especially via a Kempston interface, while the computer is switched on will damage the power resistors and regulator. Modification to voltage generator circuit: Where not fitted already, insert a 22uf capacitor between the TR4 and D15 as shown in the circuit diagram, this will ensure the correct 12v supply. On early models replace R60 by a 270 ohm resistor and fit C74 if missing. Ensure that the 12v supply is 12v. Manufacturer's advised modifications: In early versions replace all ceramic capacitors by axial ones and replace C46 by a high-temperature luf type. A l l resistors to be changed to show the second value show in centre pages circuit diagram herein; same applies to capacitors. Weak sound: Only if particularly noticeable changed to same as shown herein. Tape and Sound Circuits: should the sound section be 5Vp-p at ear socket for 2Vp-p at IC1 verifies IC1. Alignment: Only needed for early models. Place meter on pin 4 of IC4 and adjust VR1 to obtain 130mV; adjust VR2 to obtain -75raV at pin 2 with a 20mV allowable error either way. Use TC2 to set colour subcarrier frequency to 4.433619MHz to 50Hz either way. TCI only helpful to improve screen colour pattern. A l i g n m e n t : A l l models. Run the programme to display the eight colours in sequence from black to white. This is normally given as:- 10 20 30 40 50 60 FOR A=0 TO 7 FOR B=0 TO 3 PAPER A: PRINT" NEXT B NEXT A GOTO 10 "; If this shows incorrect or missing colours then align as stated for early models. See repair data for later models. 3 REPAIR DATA 1) GENERAL REPAIR PROCEDURE AND NOTES ON ALL FAULTS These computers are reportedly very unreliable with some 50% of new ones alleged to have to be returned for replacement. Many faults are due to loose or badly fitted components so that a good checkover is essential for this reason, to determine if a factory failure first. ; Check overtightened badly fitted holders, edge uncommon for heatsink first for any reported fault, is it loose? Are there screws? Look for dry joints, cracks in print or cracked boards, components, especially ICs; dirty or tarnished contacts, pins, connectors; damaged keyboard t a i l s and fins are certainly not whatever reason. Before investigating any fault check any add-ons and interfaces to the computer for broken solder, etc. caused by user wiggling them about. It is also essential to note if add-on is loose or faulty which w i l l give a guide to any damage so caused. This w i l l also determine if fault in add-on not computer. Knowing what add-ons are used can be a good guide to probable fault: for example, suspect TR4 blown and/or destroyed RAMS if a Kempton is used. Check if customer has been inserting or removing any add-ons without first switching off and point out how this practice has damaged machine and costing him unnecessary expenditure. If this is admitted then check TR4 first then RAMS and see symptom 3. 2} WONT LOAD FROM RECORDER Almost invariably this w i l l be caused by the alignment of the recorder head not being good enough. The recorder w i l l play music, etc. and function w e l l but it w i l l s t i l l need adjusted to operate the Spectrum properly and it matters not whether it is an old or just newly bought recorder. Disconnect Spectrum from recorder and with any tape playing use a long thin-bladed screwdriver to adjust the azimuth screw through the hole normally provided for this purpose. The object is to obtain the sharpest possible sounding note, noting that if note is in the least muffled sounding then there is no chance of the Spectrum loading from it. If no hole is provided this should be done with the recorder cover removed. Although it is reccomnended that volume should be set at midpoint it is far better to vary volume setting to that at which maximum treble is obtained. F i n a l l y give head a good clean and recheck setting. If the adjustment does not cure the problem then save a short programme from the computer (or use one previously saved) and if this doesn't load then it is safe to assume that there is a fault, probably in the computer. In this case, check connections to computer and the circuit from the edge connector to the first I.C. 4 Early circuit showing presets Td, TC2, VRl and VR2 to match the early type boards. Note:the different pins 16/17 setup from Id in the generalised circuit diagram shown in the middle pages. In very versionst instead of TR6 a somewhat unreliable, resistor/diode was used which should be modified as shown in the centre pages. This very unreliable circuit was used in very early versions from pin 32 to base of Id. This circuit should be modified to that shown in the centre pages if not already done. Modifications associated with IC1 3) NO COIL BUZZ FROM INVERTER, -5V ABSENT From symptom 1 it should be obvious that TR4 (ZTX650) is very prone to damage and this symptom is a sure indication that TR4 must be replaced. However, before replacing the TR4 check the TR5 (ZTX213) (using a transistor tester is O.K.) and the coil since it is not unknown for all three to have gone at the same time and if only the TR4 is replaced it can fail again immediately if the others are faulty. Whether or not these three are faulty or not, there can be one or more faulty RAMS as well caused possibly by the same forcing in of an interface during switch on. If all else has been fixed, switch on and check if any RAM gets hot; replace any very hot RAMS either in basic set or in extra board as this is a sure sign of being short circuit. If open circuit, the guickest way to check is to bye-pass each RAM in turn using a RAM known to be O.K. When so doing the same RAM must be used as the suspect and it should not be removed after each check for some ten seconds after each switch off or it will fault itself. Use of a 'scope or logic probe is clearly a better alternative if available. Tandy m<tke a good, inexpensive logic probe. 4) DIRECT CHECK FOR A SINGLE FAULTY RAM Type PRINT PEEK 23732+256 * PEEK 23733 (CR). If computer RAMS O.K. the reply is either 32767 or 85535, if less than either this means that there is a shortage of available RAMS, thus one or more RAMS may be faulty. Call the reply N and if POKE N+1,85 (CR) then PRINT PEEK N+l (CR) is typed the reply should be 85 if RAMS O . K . , in that case type POKE N+1,170 (CR) then PRINT PEEK N+l (CR) when a different number to the 170 you have just poked into that address w i l l be printed. 85 and 170 are the easiest binary numbers (01010101 and 10101010) to cover all combinations in an 8-bit chip. Where a different reply is given to either POKE locate the incorrect 1C as follows:Where 85 is poked in IC6 faulty gives 84; IC7 87; IC8 81; IC9 93; IC10 69; IC11 117; IC12 21; IC13 213. Where 170 is poked in IC15 faulty gives 171; IC16 158; IC17 174; IC18 162; IC19 186; IC20 138; IC21 234; IC22 42. 5) NO COIL BUZZ FROM INVERTER, REG7805 OPEN CIRCUIT Before replacing the 7805 check the heatsink to see if faulty or badly fitted. Remedy any physical defect in print or damage around screws, etc. Also check the TR4/5 and coil. 6) CONTINUAL FAILURE OF POWER SUPPLY TRANSISTORS Ensure that all modifications have been carried out and that the edge connector is O.K. and not loose or, damaged. Check for proper fitting of all peripherals and verify that owner is not persistently inserting/removing any of the add-ons, etc. while the computer is switched on. Note that many users are apparently incapable of grasping this simple point. Check the plug/sockets and cable, if not suitable then replace with correct ones. Check the mains and possible interference from other items on same circuit. If satisfied then check if the Ov is correct on earth. Monitor the Ov while running computer as this nay shew up an intermittent voltage fault. A systematic check on all capacitors.resistors to earth should find the culprit for this uncommon cause. 7) KEYBOARD FAULTS It is recommended that keyboards are better replaced completely since they take a lot of battering and replacement is guite inexpensive. If it is decided that the keyboard is worth repairing then tha diagram will show which tail is faulty according to keys in error. If the entire keyboard is non-functional then check the 5v supply is reaching it O.K. before replacing the ULA I.C. Probably the commonest fault lies with a faulty 10K resistor (R65 to R69) easily identified according to which keyboard co91umn is faulty. 8) VARIOUS FAULTS WHICH APPEAR ONLY WHEN WARM Check heatsink thoroughly. If heatsink is O.K. then the ULA I.C. IC1 will be the cause. If IC1 has been replaced before it may be worth adding extra heatsink for it. See also following symptom. 9) INTERMITTENT FAULTS If such faults show up with a comoaritively new Spectrum then it is most likely that they are due to poor contacts/soldering during the manufacturing process. Check all holders and pins for tarnish and dry joints. Replace faulty holders by cutting them out and replacing completely. Check after this for poor contacts or loose contacts, look for items which have been poorly soldered or even where soldering has been omitted. Finally check the boards for hairline cracks and breaks, especially radiating from heatsink screws. 10) TEXAS SN1889 INSTEAD OF LHA889 A few models appeared with the SN version and these may even have been used as replacements during repairs. Although unlikely to find now, if SN types have been used replace completely by LH type. 11) POWER SUPPLY O.K. - COMPUTER NOT WORKING CORRECTLY ; If computer is functioning at all check for single RAM failure then multiple RAM failure as already described. If RAMS are O.K. or fault is more serious and RAMS cannot be checked then check if the 5v supply is reaching all I.C.s in order IC1, 2, 24, 23, 3, 4, 26, 25 and 5. Replace the open circuit component cutting off the 5v supply if this is the case. ,' Faulty or missing sound usually identifies the ULA I.C. IC1 as being faulty and this is the most likely suspect in any case. Flick the clock crystal with your finger, this will guickly determine if it is faulty or not. Although I.C.s are best checked out systematically using a logic probe or even a 'scope, it is worth noting that after IC1 the most likely culprits are IC2 and IC5, neither of which are particularly reliable and it may even be worth replacing the three automatically as a fast check. 12) PERMANENT I.C. CHECKER FOR LOGIC PROBE USE If a logic probe is available it is well worth making a table of the results of checking each 1C pin with a good computer switched on with keyboard disconnected. Thus when any computer is being tested all that is needed is to compare the readings with your correct set and the different readings w i l l quickly pinpoint the faults. 13) FLICKERING WHITE BACKGROUND - MAY BE CAUSING EYESTRAIN If resetting the computer doesn't help, which is not uncommon if a CTV is being used, then the only thing is to set up the computer to display a coloured background with white printing. See spectrum manual for this, but green is the most relaxing background. Save this programme and load it every time Spectrum is not being used for games. 14) SPARE PARTS SUPPLIERS At time of printing the most popular suppliers appear to be:CPC Electronic Components, 194 North Road, Preston, Lanes. PV Tubes, 104 Abbey Street, Accrington, Lanes. BBS 1EE. This list may be amended in future printings. //
© Copyright 2024